[an error occurred while processing this directive] Global Geology 2018, 21(4) 245-251 DOI:   10.3969/j.issn.1673-9736.2018.04.05  ISSN: 1673-9736 CN: 22-1371/P
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gravity gradient data
spatial gradient weighting
3-D inversion
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PubMed
Inversion of gravity gradient data based on spatial gradient weighting
JIANG Dandan, YU Ping, LIN Song, GAO Xiuhe
College of Geo-Exploration Science and Technology, Changchun 130026, China
ժҪ�� Compared with traditional gravity measurement data, gravity gradient tensor data contain more high frequency information, which can be used to understand the earth's interior structure, mineral resources distribution etc. In this study, the authors present an algorithm for inverting gravity gradiometer data to recover the three-dimensional (3-D) distributions of density. Spatial gradient weighting was used to constrain the extent of the body horizontally and vertically. A more accurate inversion result can be obtained by combining the prior information into the weighting function and applying it in inversion. This method was tested on synthetic models and the inverted results showed that the resolution was significantly improved. Moreover, the algorithm was applied to the inversion of empirical data from a salt dome located in Texas, USA, which demonstrated the validity of the proposed method.
�ؼ����� gravity gradient data   spatial gradient weighting   3-D inversion  
Inversion of gravity gradient data based on spatial gradient weighting
JIANG Dandan, YU Ping, LIN Song, GAO Xiuhe
College of Geo-Exploration Science and Technology, Changchun 130026, China
Abstract: Compared with traditional gravity measurement data, gravity gradient tensor data contain more high frequency information, which can be used to understand the earth's interior structure, mineral resources distribution etc. In this study, the authors present an algorithm for inverting gravity gradiometer data to recover the three-dimensional (3-D) distributions of density. Spatial gradient weighting was used to constrain the extent of the body horizontally and vertically. A more accurate inversion result can be obtained by combining the prior information into the weighting function and applying it in inversion. This method was tested on synthetic models and the inverted results showed that the resolution was significantly improved. Moreover, the algorithm was applied to the inversion of empirical data from a salt dome located in Texas, USA, which demonstrated the validity of the proposed method.
Keywords: gravity gradient data   spatial gradient weighting   3-D inversion  
�ո����� 2018-05-11 �޻����� 2018-06-15 ����淢������  
DOI: 10.3969/j.issn.1673-9736.2018.04.05
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Supported by Project of Natural Science Fund of Jilin Province (No.20180101312JC).

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